English

Quantum proof systems for iterated exponential time, and beyond

Quantum Physics 2018-06-01 v1 Computational Complexity

Abstract

We show that any language in nondeterministic time exp(exp(exp(n)))\exp(\exp(\cdots \exp(n))), where the number of iterated exponentials is an arbitrary function R(n)R(n), can be decided by a multiprover interactive proof system with a classical polynomial-time verifier and a constant number of quantum entangled provers, with completeness 11 and soundness 1exp(Cexp(exp(n)))1 - \exp(-C\exp(\cdots\exp(n))), where the number of iterated exponentials is R(n)1R(n)-1 and C>0C>0 is a universal constant. The result was previously known for R=1R=1 and R=2R=2; we obtain it for any time-constructible function RR. The result is based on a compression technique for interactive proof systems with entangled provers that significantly simplifies and strengthens a protocol compression result of Ji (STOC'17). As a separate consequence of this technique we obtain a different proof of Slofstra's recent result (unpublished) on the uncomputability of the entangled value of multiprover games. Finally, we show that even minor improvements to our compression result would yield remarkable consequences in computational complexity theory and the foundations of quantum mechanics: first, it would imply that the class MIP* contains all computable languages; second, it would provide a negative resolution to a multipartite version of Tsirelson's problem on the relation between the commuting operator and tensor product models for quantum correlations.

Cite

@article{arxiv.1805.12166,
  title  = {Quantum proof systems for iterated exponential time, and beyond},
  author = {Joseph Fitzsimons and Zhengfeng Ji and Thomas Vidick and Henry Yuen},
  journal= {arXiv preprint arXiv:1805.12166},
  year   = {2018}
}

Comments

57 pages, comments welcome

R2 v1 2026-06-23T02:13:53.399Z